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Thu, 15 Sep 2016 17:17:15 GMTSlideShare feed for Slideshows by User: MikePinelisPhDFingerprint Sensors for Mobile and Consumer Applications -- NEW Report Sample v2https://www.slideshare.net/MikePinelisPhD/fingerprint-sensors-for-mobile-and-consumer-applications-new-report-sample-v2
160915fingerprintsensorsformobileandconsumerapplicationsreport-newsamplev2-160915171715 Fingerprint Sensors for Mobile and Consumer Applications
Market Research Report
* Fingerprint sensors in mobile and consumer applications are predominantly used for user login, mobile banking and payment, access control, privacy lock and user authentication
* Led by Apple and Samsung, the fingerprint sensor market is expected to grow four times by 2020
* In 2009 the global biometric market was $2.3B and in 2017 fingerprint sensors in smartphones alone is forecasted to reach $8.8B
* 4.5M smartphones with fingerprint sensors were shipped in 2012, 45.7M units in 2013 and a forecasted 1.6B units by 2020
* Fingerprint sensors in cell phones started appearing about 10 years ago when Fujitsu and later Motorola started integrating swipe type sensors more as a novelty
* Apple acquired fingerprint sensor technology company AuthenTec in 2012 and released the iPhone 5s with a static capacitive fingerprint sensor (Touch ID) in 2013
* In 2013, only three sensor suppliers dominated 98% of the $500M market; Apple (AuthenTec), Synaptics (Validate) and Fingerprint Cards (FPC). By 2015, a total of 13 fingerprint sensor companies were identified in an increasingly competitive industry
* The number of smartphone models with fingerprint sensors was 3 in 2012, 99 in 2015 and with continued growth expected as medium and lower end smartphones adopt fingerprint sensors
* By 2019, 50% of all smartphones are expected to include a fingerprint sensor
* Top users of fingerprint sensors in mobile handsets are predictably the three largest smartphone manufacturers Samsung (316M units), Apple (193M units) and Huawei (74M units) in the time period 2013 to 2014
* Fingerprint sensor ASPs are dropping with increased volumes and are expected to reach $2 by 2020
* The main cost factor in fabricating silicon-based fingerprint sensors is silicon, which accounts for an estimated 77% of the total material cost in sensors supplied by FPC ]]>
Fingerprint Sensors for Mobile and Consumer Applications
Market Research Report
* Fingerprint sensors in mobile and consumer applications are predominantly used for user login, mobile banking and payment, access control, privacy lock and user authentication
* Led by Apple and Samsung, the fingerprint sensor market is expected to grow four times by 2020
* In 2009 the global biometric market was $2.3B and in 2017 fingerprint sensors in smartphones alone is forecasted to reach $8.8B
* 4.5M smartphones with fingerprint sensors were shipped in 2012, 45.7M units in 2013 and a forecasted 1.6B units by 2020
* Fingerprint sensors in cell phones started appearing about 10 years ago when Fujitsu and later Motorola started integrating swipe type sensors more as a novelty
* Apple acquired fingerprint sensor technology company AuthenTec in 2012 and released the iPhone 5s with a static capacitive fingerprint sensor (Touch ID) in 2013
* In 2013, only three sensor suppliers dominated 98% of the $500M market; Apple (AuthenTec), Synaptics (Validate) and Fingerprint Cards (FPC). By 2015, a total of 13 fingerprint sensor companies were identified in an increasingly competitive industry
* The number of smartphone models with fingerprint sensors was 3 in 2012, 99 in 2015 and with continued growth expected as medium and lower end smartphones adopt fingerprint sensors
* By 2019, 50% of all smartphones are expected to include a fingerprint sensor
* Top users of fingerprint sensors in mobile handsets are predictably the three largest smartphone manufacturers Samsung (316M units), Apple (193M units) and Huawei (74M units) in the time period 2013 to 2014
* Fingerprint sensor ASPs are dropping with increased volumes and are expected to reach $2 by 2020
* The main cost factor in fabricating silicon-based fingerprint sensors is silicon, which accounts for an estimated 77% of the total material cost in sensors supplied by FPC ]]>
Thu, 15 Sep 2016 17:17:15 GMThttps://www.slideshare.net/MikePinelisPhD/fingerprint-sensors-for-mobile-and-consumer-applications-new-report-sample-v2MikePinelisPhD@slideshare.net(MikePinelisPhD)Fingerprint Sensors for Mobile and Consumer Applications -- NEW Report Sample v2MikePinelisPhDFingerprint Sensors for Mobile and Consumer Applications
Market Research Report
* Fingerprint sensors in mobile and consumer applications are predominantly used for user login, mobile banking and payment, access control, privacy lock and user authentication
* Led by Apple and Samsung, the fingerprint sensor market is expected to grow four times by 2020
* In 2009 the global biometric market was $2.3B and in 2017 fingerprint sensors in smartphones alone is forecasted to reach $8.8B
* 4.5M smartphones with fingerprint sensors were shipped in 2012, 45.7M units in 2013 and a forecasted 1.6B units by 2020
* Fingerprint sensors in cell phones started appearing about 10 years ago when Fujitsu and later Motorola started integrating swipe type sensors more as a novelty
* Apple acquired fingerprint sensor technology company AuthenTec in 2012 and released the iPhone 5s with a static capacitive fingerprint sensor (Touch ID) in 2013
* In 2013, only three sensor suppliers dominated 98% of the $500M market; Apple (AuthenTec), Synaptics (Validate) and Fingerprint Cards (FPC). By 2015, a total of 13 fingerprint sensor companies were identified in an increasingly competitive industry
* The number of smartphone models with fingerprint sensors was 3 in 2012, 99 in 2015 and with continued growth expected as medium and lower end smartphones adopt fingerprint sensors
* By 2019, 50% of all smartphones are expected to include a fingerprint sensor
* Top users of fingerprint sensors in mobile handsets are predictably the three largest smartphone manufacturers Samsung (316M units), Apple (193M units) and Huawei (74M units) in the time period 2013 to 2014
* Fingerprint sensor ASPs are dropping with increased volumes and are expected to reach $2 by 2020
* The main cost factor in fabricating silicon-based fingerprint sensors is silicon, which accounts for an estimated 77% of the total material cost in sensors supplied by FPC <img alt="" src="//cdn.slidesharecdn.com/ss_thumbnails/160915fingerprintsensorsformobileandconsumerapplicationsreport-newsamplev2-160915171715-thumbnail-2.jpg?cb=1473959886" style="border:1px solid #C3E6D8;float:right;" /><br> Fingerprint Sensors for Mobile and Consumer Applications
Market Research Report
* Fingerprint sensors in mobile and consumer applications are predominantly used for user login, mobile banking and payment, access control, privacy lock and user authentication
* Led by Apple and Samsung, the fingerprint sensor market is expected to grow four times by 2020
* In 2009 the global biometric market was $2.3B and in 2017 fingerprint sensors in smartphones alone is forecasted to reach $8.8B
* 4.5M smartphones with fingerprint sensors were shipped in 2012, 45.7M units in 2013 and a forecasted 1.6B units by 2020
* Fingerprint sensors in cell phones started appearing about 10 years ago when Fujitsu and later Motorola started integrating swipe type sensors more as a novelty
* Apple acquired fingerprint sensor technology company AuthenTec in 2012 and released the iPhone 5s with a static capacitive fingerprint sensor (Touch ID) in 2013
* In 2013, only three sensor suppliers dominated 98% of the $500M market; Apple (AuthenTec), Synaptics (Validate) and Fingerprint Cards (FPC). By 2015, a total of 13 fingerprint sensor companies were identified in an increasingly competitive industry
* The number of smartphone models with fingerprint sensors was 3 in 2012, 99 in 2015 and with continued growth expected as medium and lower end smartphones adopt fingerprint sensors
* By 2019, 50% of all smartphones are expected to include a fingerprint sensor
* Top users of fingerprint sensors in mobile handsets are predictably the three largest smartphone manufacturers Samsung (316M units), Apple (193M units) and Huawei (74M units) in the time period 2013 to 2014
* Fingerprint sensor ASPs are dropping with increased volumes and are expected to reach $2 by 2020
* The main cost factor in fabricating silicon-based fingerprint sensors is silicon, which accounts for an estimated 77% of the total material cost in sensors supplied by FPC

]]>
17620//cdn.slidesharecdn.com/ss_thumbnails/160915fingerprintsensorsformobileandconsumerapplicationsreport-newsamplev2-160915171715-thumbnail-2.jpg?cb=1473959886presentationBlackhttp://activitystrea.ms/schema/1.0/posthttp://activitystrea.ms/schema/1.0/posted1Sensor Hubs for Mobile and Consumer Electronics Applications -- New Report Samplehttps://www.slideshare.net/MikePinelisPhD/sensor-hubs-for-mobile-and-consumer-electronics-applications-new-report-sample
160817sensorhubstechnologyreport-final-samplenew-160818032857 Sensor hubs have become ubiquitous in smartphones and wearable devices over the past few years. They first started out as discrete MCUs for offloading sensor functions from the application processor (AP) to a lower-power processor to preserve battery power while the main AP is "sleeping".
In 2013, Apple introduced the M7 discrete sensor hub from NXP for motion sensing in the iPhone 5s and Samsung released the Galaxy S4 with a discrete sensor hub from Atmel. Qualcomm had already launched versions of the popular Snapdragon application processor with integrated low-power sensor core for smartphones a few years earlier, and in 2015, Google launched the Android Sensor Hub.
This report provides a comprehensive overview of the technologies and market for sensor hubs for mobile and consumer electronics applications, and addresses several key questions such as:
● What are the main usual sensor hub architectures and sensor hub types?
● What are the applications, opportunities, and recent developments for sensor hubs?
● What are the emerging trends with sensor hub technologies?
● Who are the main players in the sensor hub space?
The report contains the following sections:
● Executive summary
● Sensor hubs overview and introduction -- overview of sensor hubs in consumer and mobile applications, including types of applications, market size and growth, and industry trends
● Sensor hub architectures -- comprehensive review of the history of sensor hubs, available architectures, operating system compatibility and system level integration
● Sensor hub types, features, and functionality -- complete review of available sensor hub types, detailed comparison of sensor hubs and how future sensor hubs are shaped by market forces
● Sensor hub applications -- analysis of how sensor hubs are being used in consumer and mobile applications, challenges in system integration and emerging technologies
● Sensor hub main players -- close look at main sensor hub suppliers, partnerships and acquisitions
● Sensor hub platforms and ecosystems -- Examples of development platforms and how developers can use these, proprietary technology advantages and issues pertaining to data privacy and security
● Related technologies -- presentation of related technologies impacting how sensor hubs are being designed, developed, integrated and used
● Recent sensor hub developments
For more information or to discuss your project with us, please email us at mr@memsjournal.com]]>
Sensor hubs have become ubiquitous in smartphones and wearable devices over the past few years. They first started out as discrete MCUs for offloading sensor functions from the application processor (AP) to a lower-power processor to preserve battery power while the main AP is "sleeping".
In 2013, Apple introduced the M7 discrete sensor hub from NXP for motion sensing in the iPhone 5s and Samsung released the Galaxy S4 with a discrete sensor hub from Atmel. Qualcomm had already launched versions of the popular Snapdragon application processor with integrated low-power sensor core for smartphones a few years earlier, and in 2015, Google launched the Android Sensor Hub.
This report provides a comprehensive overview of the technologies and market for sensor hubs for mobile and consumer electronics applications, and addresses several key questions such as:
● What are the main usual sensor hub architectures and sensor hub types?
● What are the applications, opportunities, and recent developments for sensor hubs?
● What are the emerging trends with sensor hub technologies?
● Who are the main players in the sensor hub space?
The report contains the following sections:
● Executive summary
● Sensor hubs overview and introduction -- overview of sensor hubs in consumer and mobile applications, including types of applications, market size and growth, and industry trends
● Sensor hub architectures -- comprehensive review of the history of sensor hubs, available architectures, operating system compatibility and system level integration
● Sensor hub types, features, and functionality -- complete review of available sensor hub types, detailed comparison of sensor hubs and how future sensor hubs are shaped by market forces
● Sensor hub applications -- analysis of how sensor hubs are being used in consumer and mobile applications, challenges in system integration and emerging technologies
● Sensor hub main players -- close look at main sensor hub suppliers, partnerships and acquisitions
● Sensor hub platforms and ecosystems -- Examples of development platforms and how developers can use these, proprietary technology advantages and issues pertaining to data privacy and security
● Related technologies -- presentation of related technologies impacting how sensor hubs are being designed, developed, integrated and used
● Recent sensor hub developments
For more information or to discuss your project with us, please email us at mr@memsjournal.com]]>
Thu, 18 Aug 2016 03:28:57 GMThttps://www.slideshare.net/MikePinelisPhD/sensor-hubs-for-mobile-and-consumer-electronics-applications-new-report-sampleMikePinelisPhD@slideshare.net(MikePinelisPhD)Sensor Hubs for Mobile and Consumer Electronics Applications -- New Report SampleMikePinelisPhDSensor hubs have become ubiquitous in smartphones and wearable devices over the past few years. They first started out as discrete MCUs for offloading sensor functions from the application processor (AP) to a lower-power processor to preserve battery power while the main AP is "sleeping".
In 2013, Apple introduced the M7 discrete sensor hub from NXP for motion sensing in the iPhone 5s and Samsung released the Galaxy S4 with a discrete sensor hub from Atmel. Qualcomm had already launched versions of the popular Snapdragon application processor with integrated low-power sensor core for smartphones a few years earlier, and in 2015, Google launched the Android Sensor Hub.
This report provides a comprehensive overview of the technologies and market for sensor hubs for mobile and consumer electronics applications, and addresses several key questions such as:
● What are the main usual sensor hub architectures and sensor hub types?
● What are the applications, opportunities, and recent developments for sensor hubs?
● What are the emerging trends with sensor hub technologies?
● Who are the main players in the sensor hub space?
The report contains the following sections:
● Executive summary
● Sensor hubs overview and introduction -- overview of sensor hubs in consumer and mobile applications, including types of applications, market size and growth, and industry trends
● Sensor hub architectures -- comprehensive review of the history of sensor hubs, available architectures, operating system compatibility and system level integration
● Sensor hub types, features, and functionality -- complete review of available sensor hub types, detailed comparison of sensor hubs and how future sensor hubs are shaped by market forces
● Sensor hub applications -- analysis of how sensor hubs are being used in consumer and mobile applications, challenges in system integration and emerging technologies
● Sensor hub main players -- close look at main sensor hub suppliers, partnerships and acquisitions
● Sensor hub platforms and ecosystems -- Examples of development platforms and how developers can use these, proprietary technology advantages and issues pertaining to data privacy and security
● Related technologies -- presentation of related technologies impacting how sensor hubs are being designed, developed, integrated and used
● Recent sensor hub developments
For more information or to discuss your project with us, please email us at mr@memsjournal.com<img alt="" src="//cdn.slidesharecdn.com/ss_thumbnails/160817sensorhubstechnologyreport-final-samplenew-160818032857-thumbnail-2.jpg?cb=1471491022" style="border:1px solid #C3E6D8;float:right;" /><br> Sensor hubs have become ubiquitous in smartphones and wearable devices over the past few years. They first started out as discrete MCUs for offloading sensor functions from the application processor (AP) to a lower-power processor to preserve battery power while the main AP is &quot;sleeping&quot;.
In 2013, Apple introduced the M7 discrete sensor hub from NXP for motion sensing in the iPhone 5s and Samsung released the Galaxy S4 with a discrete sensor hub from Atmel. Qualcomm had already launched versions of the popular Snapdragon application processor with integrated low-power sensor core for smartphones a few years earlier, and in 2015, Google launched the Android Sensor Hub.
This report provides a comprehensive overview of the technologies and market for sensor hubs for mobile and consumer electronics applications, and addresses several key questions such as:
● What are the main usual sensor hub architectures and sensor hub types?
● What are the applications, opportunities, and recent developments for sensor hubs?
● What are the emerging trends with sensor hub technologies?
● Who are the main players in the sensor hub space?
The report contains the following sections:
● Executive summary
● Sensor hubs overview and introduction -- overview of sensor hubs in consumer and mobile applications, including types of applications, market size and growth, and industry trends
● Sensor hub architectures -- comprehensive review of the history of sensor hubs, available architectures, operating system compatibility and system level integration
● Sensor hub types, features, and functionality -- complete review of available sensor hub types, detailed comparison of sensor hubs and how future sensor hubs are shaped by market forces
● Sensor hub applications -- analysis of how sensor hubs are being used in consumer and mobile applications, challenges in system integration and emerging technologies
● Sensor hub main players -- close look at main sensor hub suppliers, partnerships and acquisitions
● Sensor hub platforms and ecosystems -- Examples of development platforms and how developers can use these, proprietary technology advantages and issues pertaining to data privacy and security
● Related technologies -- presentation of related technologies impacting how sensor hubs are being designed, developed, integrated and used
● Recent sensor hub developments
For more information or to discuss your project with us, please email us at mr@memsjournal.com

]]>
7880//cdn.slidesharecdn.com/ss_thumbnails/160817sensorhubstechnologyreport-final-samplenew-160818032857-thumbnail-2.jpg?cb=1471491022presentationBlackhttp://activitystrea.ms/schema/1.0/posthttp://activitystrea.ms/schema/1.0/posted1Sensor Hubs for Mobile and Consumer Electronics Applicationshttps://www.slideshare.net/MikePinelisPhD/sensor-hubs-for-mobile-and-consumer-electronics-applications
160815sensorhubstechnologyreport-final-sample-160816030353 Sensor hubs have become ubiquitous in smartphones and wearable devices over the past few years. They first started out as discrete MCUs for offloading sensor functions from the application processor (AP) to a lower-power processor to preserve battery power while the main AP is "sleeping".
In 2013, Apple introduced the M7 discrete sensor hub from NXP for motion sensing in the iPhone 5s and Samsung released the Galaxy S4 with a discrete sensor hub from Atmel. Qualcomm had already launched versions of the popular Snapdragon application processor with integrated low-power sensor core for smartphones a few years earlier, and in 2015, Google launched the Android Sensor Hub.
This report provides a comprehensive overview of the technologies and market for sensor hubs for mobile and consumer electronics applications, and addresses several key questions such as:
● What are the main usual sensor hub architectures and sensor hub types?
● What are the applications, opportunities, and recent developments for sensor hubs?
● What are the emerging trends with sensor hub technologies?
● Who are the main players in the sensor hub space?
The report contains the following sections:
● Executive summary
● Sensor hubs overview and introduction -- overview of sensor hubs in consumer and mobile applications, including types of applications, market size and growth, and industry trends
● Sensor hub architectures -- comprehensive review of the history of sensor hubs, available architectures, operating system compatibility and system level integration
● Sensor hub types, features, and functionality -- complete review of available sensor hub types, detailed comparison of sensor hubs and how future sensor hubs are shaped by market forces
● Sensor hub applications -- analysis of how sensor hubs are being used in consumer and mobile applications, challenges in system integration and emerging technologies
● Sensor hub main players -- close look at main sensor hub suppliers, partnerships and acquisitions
● Sensor hub platforms and ecosystems -- Examples of development platforms and how developers can use these, proprietary technology advantages and issues pertaining to data privacy and security
● Related technologies -- presentation of related technologies impacting how sensor hubs are being designed, developed, integrated and used
● Recent sensor hub developments
For more information or to discuss your project with us, please email us at mr@memsjournal.com
]]>
Sensor hubs have become ubiquitous in smartphones and wearable devices over the past few years. They first started out as discrete MCUs for offloading sensor functions from the application processor (AP) to a lower-power processor to preserve battery power while the main AP is "sleeping".
In 2013, Apple introduced the M7 discrete sensor hub from NXP for motion sensing in the iPhone 5s and Samsung released the Galaxy S4 with a discrete sensor hub from Atmel. Qualcomm had already launched versions of the popular Snapdragon application processor with integrated low-power sensor core for smartphones a few years earlier, and in 2015, Google launched the Android Sensor Hub.
This report provides a comprehensive overview of the technologies and market for sensor hubs for mobile and consumer electronics applications, and addresses several key questions such as:
● What are the main usual sensor hub architectures and sensor hub types?
● What are the applications, opportunities, and recent developments for sensor hubs?
● What are the emerging trends with sensor hub technologies?
● Who are the main players in the sensor hub space?
The report contains the following sections:
● Executive summary
● Sensor hubs overview and introduction -- overview of sensor hubs in consumer and mobile applications, including types of applications, market size and growth, and industry trends
● Sensor hub architectures -- comprehensive review of the history of sensor hubs, available architectures, operating system compatibility and system level integration
● Sensor hub types, features, and functionality -- complete review of available sensor hub types, detailed comparison of sensor hubs and how future sensor hubs are shaped by market forces
● Sensor hub applications -- analysis of how sensor hubs are being used in consumer and mobile applications, challenges in system integration and emerging technologies
● Sensor hub main players -- close look at main sensor hub suppliers, partnerships and acquisitions
● Sensor hub platforms and ecosystems -- Examples of development platforms and how developers can use these, proprietary technology advantages and issues pertaining to data privacy and security
● Related technologies -- presentation of related technologies impacting how sensor hubs are being designed, developed, integrated and used
● Recent sensor hub developments
For more information or to discuss your project with us, please email us at mr@memsjournal.com
]]>
Tue, 16 Aug 2016 03:03:53 GMThttps://www.slideshare.net/MikePinelisPhD/sensor-hubs-for-mobile-and-consumer-electronics-applicationsMikePinelisPhD@slideshare.net(MikePinelisPhD)Sensor Hubs for Mobile and Consumer Electronics ApplicationsMikePinelisPhDSensor hubs have become ubiquitous in smartphones and wearable devices over the past few years. They first started out as discrete MCUs for offloading sensor functions from the application processor (AP) to a lower-power processor to preserve battery power while the main AP is "sleeping".
In 2013, Apple introduced the M7 discrete sensor hub from NXP for motion sensing in the iPhone 5s and Samsung released the Galaxy S4 with a discrete sensor hub from Atmel. Qualcomm had already launched versions of the popular Snapdragon application processor with integrated low-power sensor core for smartphones a few years earlier, and in 2015, Google launched the Android Sensor Hub.
This report provides a comprehensive overview of the technologies and market for sensor hubs for mobile and consumer electronics applications, and addresses several key questions such as:
● What are the main usual sensor hub architectures and sensor hub types?
● What are the applications, opportunities, and recent developments for sensor hubs?
● What are the emerging trends with sensor hub technologies?
● Who are the main players in the sensor hub space?
The report contains the following sections:
● Executive summary
● Sensor hubs overview and introduction -- overview of sensor hubs in consumer and mobile applications, including types of applications, market size and growth, and industry trends
● Sensor hub architectures -- comprehensive review of the history of sensor hubs, available architectures, operating system compatibility and system level integration
● Sensor hub types, features, and functionality -- complete review of available sensor hub types, detailed comparison of sensor hubs and how future sensor hubs are shaped by market forces
● Sensor hub applications -- analysis of how sensor hubs are being used in consumer and mobile applications, challenges in system integration and emerging technologies
● Sensor hub main players -- close look at main sensor hub suppliers, partnerships and acquisitions
● Sensor hub platforms and ecosystems -- Examples of development platforms and how developers can use these, proprietary technology advantages and issues pertaining to data privacy and security
● Related technologies -- presentation of related technologies impacting how sensor hubs are being designed, developed, integrated and used
● Recent sensor hub developments
For more information or to discuss your project with us, please email us at mr@memsjournal.com
<img alt="" src="//cdn.slidesharecdn.com/ss_thumbnails/160815sensorhubstechnologyreport-final-sample-160816030353-thumbnail-2.jpg?cb=1471370409" style="border:1px solid #C3E6D8;float:right;" /><br> Sensor hubs have become ubiquitous in smartphones and wearable devices over the past few years. They first started out as discrete MCUs for offloading sensor functions from the application processor (AP) to a lower-power processor to preserve battery power while the main AP is &quot;sleeping&quot;.
In 2013, Apple introduced the M7 discrete sensor hub from NXP for motion sensing in the iPhone 5s and Samsung released the Galaxy S4 with a discrete sensor hub from Atmel. Qualcomm had already launched versions of the popular Snapdragon application processor with integrated low-power sensor core for smartphones a few years earlier, and in 2015, Google launched the Android Sensor Hub.
This report provides a comprehensive overview of the technologies and market for sensor hubs for mobile and consumer electronics applications, and addresses several key questions such as:
● What are the main usual sensor hub architectures and sensor hub types?
● What are the applications, opportunities, and recent developments for sensor hubs?
● What are the emerging trends with sensor hub technologies?
● Who are the main players in the sensor hub space?
The report contains the following sections:
● Executive summary
● Sensor hubs overview and introduction -- overview of sensor hubs in consumer and mobile applications, including types of applications, market size and growth, and industry trends
● Sensor hub architectures -- comprehensive review of the history of sensor hubs, available architectures, operating system compatibility and system level integration
● Sensor hub types, features, and functionality -- complete review of available sensor hub types, detailed comparison of sensor hubs and how future sensor hubs are shaped by market forces
● Sensor hub applications -- analysis of how sensor hubs are being used in consumer and mobile applications, challenges in system integration and emerging technologies
● Sensor hub main players -- close look at main sensor hub suppliers, partnerships and acquisitions
● Sensor hub platforms and ecosystems -- Examples of development platforms and how developers can use these, proprietary technology advantages and issues pertaining to data privacy and security
● Related technologies -- presentation of related technologies impacting how sensor hubs are being designed, developed, integrated and used
● Recent sensor hub developments
For more information or to discuss your project with us, please email us at mr@memsjournal.com

]]>
43010//cdn.slidesharecdn.com/ss_thumbnails/160815sensorhubstechnologyreport-final-sample-160816030353-thumbnail-2.jpg?cb=1471370409presentationBlackhttp://activitystrea.ms/schema/1.0/posthttp://activitystrea.ms/schema/1.0/posted13D Packaging and TSV Technologies -- Market Research Databasehttps://www.slideshare.net/MikePinelisPhD/3d-packaging-and-tsv-technologies-market-research-database
1607183dpackagingandtsvtechnologiesdatabase-brochureanddescription-160720164724 MEMS Journal has conducted the largest industry survey on emerging opportunities and challenges for 3D packaging and TSV technologies.
This survey includes most of the players in the semiconductor ecosystem including, but not limited to, MEMS and sensor technology companies.
During the course of this study, we’ve reached out to 3,500+ individuals and have received more than 570 responses.
Each respondent has provided us with approximately one page of feedback on their existing 3D packaging and TSV projects, as well as their specific current challenges.
We are now making the results of this survey available as a market research and intelligence database.
This information will be useful for companies which are developing strategic plans and roadmaps for their next generation products and services. The database will also be useful for sales and business development people as a source of new leads.
This market research database provides the following benefits:
market research and intelligence data around the topic of advanced packaging including 3D packaging, TSV, and WLP technologies
more than 570 pages of direct feedback from the key industry participants who have outlined their needs and priorities as related to core product and service offerings
new business leads for your sales and business development team; the database includes contact information for all of the survey participants it is easy to get in touch with them directly to discuss business and partnership opportunities.
vital competitive and market intelligence for your strategy development and roadmap efforts; we’ve spent 24+ months to conduct this survey and you will get all of the results to instantly obtain an advantage in the marketplace
For more information about MEMS Journal, please go to http://www.memsjournal.com]]>
MEMS Journal has conducted the largest industry survey on emerging opportunities and challenges for 3D packaging and TSV technologies.
This survey includes most of the players in the semiconductor ecosystem including, but not limited to, MEMS and sensor technology companies.
During the course of this study, we’ve reached out to 3,500+ individuals and have received more than 570 responses.
Each respondent has provided us with approximately one page of feedback on their existing 3D packaging and TSV projects, as well as their specific current challenges.
We are now making the results of this survey available as a market research and intelligence database.
This information will be useful for companies which are developing strategic plans and roadmaps for their next generation products and services. The database will also be useful for sales and business development people as a source of new leads.
This market research database provides the following benefits:
market research and intelligence data around the topic of advanced packaging including 3D packaging, TSV, and WLP technologies
more than 570 pages of direct feedback from the key industry participants who have outlined their needs and priorities as related to core product and service offerings
new business leads for your sales and business development team; the database includes contact information for all of the survey participants it is easy to get in touch with them directly to discuss business and partnership opportunities.
vital competitive and market intelligence for your strategy development and roadmap efforts; we’ve spent 24+ months to conduct this survey and you will get all of the results to instantly obtain an advantage in the marketplace
For more information about MEMS Journal, please go to http://www.memsjournal.com]]>
Wed, 20 Jul 2016 16:47:23 GMThttps://www.slideshare.net/MikePinelisPhD/3d-packaging-and-tsv-technologies-market-research-databaseMikePinelisPhD@slideshare.net(MikePinelisPhD)3D Packaging and TSV Technologies -- Market Research DatabaseMikePinelisPhDMEMS Journal has conducted the largest industry survey on emerging opportunities and challenges for 3D packaging and TSV technologies.
This survey includes most of the players in the semiconductor ecosystem including, but not limited to, MEMS and sensor technology companies.
During the course of this study, we’ve reached out to 3,500+ individuals and have received more than 570 responses.
Each respondent has provided us with approximately one page of feedback on their existing 3D packaging and TSV projects, as well as their specific current challenges.
We are now making the results of this survey available as a market research and intelligence database.
This information will be useful for companies which are developing strategic plans and roadmaps for their next generation products and services. The database will also be useful for sales and business development people as a source of new leads.
This market research database provides the following benefits:
market research and intelligence data around the topic of advanced packaging including 3D packaging, TSV, and WLP technologies
more than 570 pages of direct feedback from the key industry participants who have outlined their needs and priorities as related to core product and service offerings
new business leads for your sales and business development team; the database includes contact information for all of the survey participants it is easy to get in touch with them directly to discuss business and partnership opportunities.
vital competitive and market intelligence for your strategy development and roadmap efforts; we’ve spent 24+ months to conduct this survey and you will get all of the results to instantly obtain an advantage in the marketplace
For more information about MEMS Journal, please go to http://www.memsjournal.com<img alt="" src="//cdn.slidesharecdn.com/ss_thumbnails/1607183dpackagingandtsvtechnologiesdatabase-brochureanddescription-160720164724-thumbnail-2.jpg?cb=1469460291" style="border:1px solid #C3E6D8;float:right;" /><br> MEMS Journal has conducted the largest industry survey on emerging opportunities and challenges for 3D packaging and TSV technologies.
This survey includes most of the players in the semiconductor ecosystem including, but not limited to, MEMS and sensor technology companies.
During the course of this study, we’ve reached out to 3,500+ individuals and have received more than 570 responses.
Each respondent has provided us with approximately one page of feedback on their existing 3D packaging and TSV projects, as well as their specific current challenges.
We are now making the results of this survey available as a market research and intelligence database.
This information will be useful for companies which are developing strategic plans and roadmaps for their next generation products and services. The database will also be useful for sales and business development people as a source of new leads.
This market research database provides the following benefits:
market research and intelligence data around the topic of advanced packaging including 3D packaging, TSV, and WLP technologies
more than 570 pages of direct feedback from the key industry participants who have outlined their needs and priorities as related to core product and service offerings
new business leads for your sales and business development team; the database includes contact information for all of the survey participants it is easy to get in touch with them directly to discuss business and partnership opportunities.
vital competitive and market intelligence for your strategy development and roadmap efforts; we’ve spent 24+ months to conduct this survey and you will get all of the results to instantly obtain an advantage in the marketplace
For more information about MEMS Journal, please go to http://www.memsjournal.com

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9850//cdn.slidesharecdn.com/ss_thumbnails/1607183dpackagingandtsvtechnologiesdatabase-brochureanddescription-160720164724-thumbnail-2.jpg?cb=1469460291presentationBlackhttp://activitystrea.ms/schema/1.0/posthttp://activitystrea.ms/schema/1.0/posted1ASICs Development for MEMS Applications: A Platform Approachhttps://www.slideshare.net/MikePinelisPhD/asics-for-mems-a-platform-approach
160608memsasicplatformapproachsi-ware-160630205039 For more information, go to http://www.si-ware.com/asic-solutions or contact Scott Smyser at scott.smyser@si-ware.com or +1-818-790-1151, x101.
Advances in MEMS manufacturing and packaging technologies
More and more companies are doing MEMS
•Established semiconductor companies adding MEMS capabilities
•Many startups emerging with very promising MEMS devices
More access to MEMS + exploding market = increased competition
•Quick development time required
•MEMS development already challenging
•ASIC development requires a solid understanding of the MEMS
•If MEMS is not validated then relying on models]]>
For more information, go to http://www.si-ware.com/asic-solutions or contact Scott Smyser at scott.smyser@si-ware.com or +1-818-790-1151, x101.
Advances in MEMS manufacturing and packaging technologies
More and more companies are doing MEMS
•Established semiconductor companies adding MEMS capabilities
•Many startups emerging with very promising MEMS devices
More access to MEMS + exploding market = increased competition
•Quick development time required
•MEMS development already challenging
•ASIC development requires a solid understanding of the MEMS
•If MEMS is not validated then relying on models]]>
Thu, 30 Jun 2016 20:50:39 GMThttps://www.slideshare.net/MikePinelisPhD/asics-for-mems-a-platform-approachMikePinelisPhD@slideshare.net(MikePinelisPhD)ASICs Development for MEMS Applications: A Platform ApproachMikePinelisPhDFor more information, go to http://www.si-ware.com/asic-solutions or contact Scott Smyser at scott.smyser@si-ware.com or +1-818-790-1151, x101.
Advances in MEMS manufacturing and packaging technologies
More and more companies are doing MEMS
•Established semiconductor companies adding MEMS capabilities
•Many startups emerging with very promising MEMS devices
More access to MEMS + exploding market = increased competition
•Quick development time required
•MEMS development already challenging
•ASIC development requires a solid understanding of the MEMS
•If MEMS is not validated then relying on models<img alt="" src="//cdn.slidesharecdn.com/ss_thumbnails/160608memsasicplatformapproachsi-ware-160630205039-thumbnail-2.jpg?cb=1467320091" style="border:1px solid #C3E6D8;float:right;" /><br> For more information, go to http://www.si-ware.com/asic-solutions or contact Scott Smyser at scott.smyser@si-ware.com or +1-818-790-1151, x101.
Advances in MEMS manufacturing and packaging technologies
More and more companies are doing MEMS
•Established semiconductor companies adding MEMS capabilities
•Many startups emerging with very promising MEMS devices
More access to MEMS + exploding market = increased competition
•Quick development time required
•MEMS development already challenging
•ASIC development requires a solid understanding of the MEMS
•If MEMS is not validated then relying on models

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16470//cdn.slidesharecdn.com/ss_thumbnails/160608memsasicplatformapproachsi-ware-160630205039-thumbnail-2.jpg?cb=1467320091presentationBlackhttp://activitystrea.ms/schema/1.0/posthttp://activitystrea.ms/schema/1.0/posted1Parylene for Flexible Electronicshttps://www.slideshare.net/MikePinelisPhD/parylene-for-flexible-electronics
160124diamond-mtparyleneforflexibleelectronicspresentation-160630142016 • Flexible electronics or flex circuits is a technology used to assemble electronic circuits on flexible plastic substrates as an alternative to rigid, printed circuit boards or PCBs
• Flexible printed circuits (FPCs) are made using photolithography and flexible flat cables (FFC) are laminates of very thin copper strips, sandwiched between two layers of PET
• FPCs are easy to manufacture and standard surface mount (SMT) components can be assembled on the flex substrate
• Single-sided FPCs are perfect for dynamic and high-flex applications
• Flex circuits can be made to conform to a desired shape or flex during use. Everyday electronic devices contain flex circuitry, like the camera in the image below]]>
• Flexible electronics or flex circuits is a technology used to assemble electronic circuits on flexible plastic substrates as an alternative to rigid, printed circuit boards or PCBs
• Flexible printed circuits (FPCs) are made using photolithography and flexible flat cables (FFC) are laminates of very thin copper strips, sandwiched between two layers of PET
• FPCs are easy to manufacture and standard surface mount (SMT) components can be assembled on the flex substrate
• Single-sided FPCs are perfect for dynamic and high-flex applications
• Flex circuits can be made to conform to a desired shape or flex during use. Everyday electronic devices contain flex circuitry, like the camera in the image below]]>
Thu, 30 Jun 2016 14:20:15 GMThttps://www.slideshare.net/MikePinelisPhD/parylene-for-flexible-electronicsMikePinelisPhD@slideshare.net(MikePinelisPhD)Parylene for Flexible ElectronicsMikePinelisPhD• Flexible electronics or flex circuits is a technology used to assemble electronic circuits on flexible plastic substrates as an alternative to rigid, printed circuit boards or PCBs
• Flexible printed circuits (FPCs) are made using photolithography and flexible flat cables (FFC) are laminates of very thin copper strips, sandwiched between two layers of PET
• FPCs are easy to manufacture and standard surface mount (SMT) components can be assembled on the flex substrate
• Single-sided FPCs are perfect for dynamic and high-flex applications
• Flex circuits can be made to conform to a desired shape or flex during use. Everyday electronic devices contain flex circuitry, like the camera in the image below<img alt="" src="//cdn.slidesharecdn.com/ss_thumbnails/160124diamond-mtparyleneforflexibleelectronicspresentation-160630142016-thumbnail-2.jpg?cb=1467296649" style="border:1px solid #C3E6D8;float:right;" /><br> • Flexible electronics or flex circuits is a technology used to assemble electronic circuits on flexible plastic substrates as an alternative to rigid, printed circuit boards or PCBs
• Flexible printed circuits (FPCs) are made using photolithography and flexible flat cables (FFC) are laminates of very thin copper strips, sandwiched between two layers of PET
• FPCs are easy to manufacture and standard surface mount (SMT) components can be assembled on the flex substrate
• Single-sided FPCs are perfect for dynamic and high-flex applications
• Flex circuits can be made to conform to a desired shape or flex during use. Everyday electronic devices contain flex circuitry, like the camera in the image below

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10330//cdn.slidesharecdn.com/ss_thumbnails/160124diamond-mtparyleneforflexibleelectronicspresentation-160630142016-thumbnail-2.jpg?cb=1467296649presentationBlackhttp://activitystrea.ms/schema/1.0/posthttp://activitystrea.ms/schema/1.0/posted1Microfluidics company database -- brochure and descriptionhttps://www.slideshare.net/MikePinelisPhD/microfluidics-company-database-brochure-and-description
160627microfluidicscompanydatabase-brochureanddescription-160629191435 We've developed the most comprehensive and largest database with focused on microfluidics companies and commercialized products. The database includes only companies with commercialized products, not R&D projects or university efforts. Thus, all of the companies in this database have active needs and many of these companies are already producing their devices in high volume.
Here are the way you can use this database to benefit your business:
1) Connect with new potential customers before your competitors do.
2) Gain a better understanding of the technology trends and marketplace dynamics.
3) Identify and contact new potential partners.
4) Recruit key executives and engineers to your team.
5) Identify potential investment opportunities.
6) Get a comprehensive view of commercialized products based on microfluidics technologies.
7) Accelerate your sales cycle by obtaining more information about your prospective customers.
]]>
We've developed the most comprehensive and largest database with focused on microfluidics companies and commercialized products. The database includes only companies with commercialized products, not R&D projects or university efforts. Thus, all of the companies in this database have active needs and many of these companies are already producing their devices in high volume.
Here are the way you can use this database to benefit your business:
1) Connect with new potential customers before your competitors do.
2) Gain a better understanding of the technology trends and marketplace dynamics.
3) Identify and contact new potential partners.
4) Recruit key executives and engineers to your team.
5) Identify potential investment opportunities.
6) Get a comprehensive view of commercialized products based on microfluidics technologies.
7) Accelerate your sales cycle by obtaining more information about your prospective customers.
]]>
Wed, 29 Jun 2016 19:14:35 GMThttps://www.slideshare.net/MikePinelisPhD/microfluidics-company-database-brochure-and-descriptionMikePinelisPhD@slideshare.net(MikePinelisPhD)Microfluidics company database -- brochure and descriptionMikePinelisPhDWe've developed the most comprehensive and largest database with focused on microfluidics companies and commercialized products. The database includes only companies with commercialized products, not R&D projects or university efforts. Thus, all of the companies in this database have active needs and many of these companies are already producing their devices in high volume.
Here are the way you can use this database to benefit your business:
1) Connect with new potential customers before your competitors do.
2) Gain a better understanding of the technology trends and marketplace dynamics.
3) Identify and contact new potential partners.
4) Recruit key executives and engineers to your team.
5) Identify potential investment opportunities.
6) Get a comprehensive view of commercialized products based on microfluidics technologies.
7) Accelerate your sales cycle by obtaining more information about your prospective customers.
<img alt="" src="//cdn.slidesharecdn.com/ss_thumbnails/160627microfluidicscompanydatabase-brochureanddescription-160629191435-thumbnail-2.jpg?cb=1467252059" style="border:1px solid #C3E6D8;float:right;" /><br> We&#39;ve developed the most comprehensive and largest database with focused on microfluidics companies and commercialized products. The database includes only companies with commercialized products, not R&amp;D projects or university efforts. Thus, all of the companies in this database have active needs and many of these companies are already producing their devices in high volume.
Here are the way you can use this database to benefit your business:
1) Connect with new potential customers before your competitors do.
2) Gain a better understanding of the technology trends and marketplace dynamics.
3) Identify and contact new potential partners.
4) Recruit key executives and engineers to your team.
5) Identify potential investment opportunities.
6) Get a comprehensive view of commercialized products based on microfluidics technologies.
7) Accelerate your sales cycle by obtaining more information about your prospective customers.

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39720//cdn.slidesharecdn.com/ss_thumbnails/160627microfluidicscompanydatabase-brochureanddescription-160629191435-thumbnail-2.jpg?cb=1467252059presentationBlackhttp://activitystrea.ms/schema/1.0/posthttp://activitystrea.ms/schema/1.0/posted1Smart Contact Lenses Technologies -- market research report (sample)https://www.slideshare.net/MikePinelisPhD/smart-contact-lenses-technologies-market-research-report-sample
151019smartcontactlensesreport-sample-151019205413-lva1-app6891 With nearly one billion units shipped worldwide in 2015 and annual growth rate of 6-7%, contact lenses are already a huge business. Smart contact lenses can potentially become an even larger market and present a unique business opportunity. Unlike other types of wearable devices such as activity trackers, smart contact lenses are only in the early stages of the commercialization cycle and, as such, provide a lucrative target for investors, system developers, sensor makers, and medical device companies.
This detailed 131-slide report provides a comprehensive overview of start contact lenses technologies and addresses several key questions such as:
● What are the applications and opportunities for smart contact lenses?
● Who are the main players in the smart contact lens space?
● What intellectual property (IP) is being developed for smart contact lenses?
● Which flexible technologies are being used or have the potential to be used?
● What are the existing and emerging applications?
● What are the key related technologies such as ocular implants, smart glasses, as well as virtual and augmented reality?
● Who are the key players and participants from R&D and commercialization perspective?
To order the full version, please go here: https://fs8.formsite.com/medved44/form33/index.html ]]>
With nearly one billion units shipped worldwide in 2015 and annual growth rate of 6-7%, contact lenses are already a huge business. Smart contact lenses can potentially become an even larger market and present a unique business opportunity. Unlike other types of wearable devices such as activity trackers, smart contact lenses are only in the early stages of the commercialization cycle and, as such, provide a lucrative target for investors, system developers, sensor makers, and medical device companies.
This detailed 131-slide report provides a comprehensive overview of start contact lenses technologies and addresses several key questions such as:
● What are the applications and opportunities for smart contact lenses?
● Who are the main players in the smart contact lens space?
● What intellectual property (IP) is being developed for smart contact lenses?
● Which flexible technologies are being used or have the potential to be used?
● What are the existing and emerging applications?
● What are the key related technologies such as ocular implants, smart glasses, as well as virtual and augmented reality?
● Who are the key players and participants from R&D and commercialization perspective?
To order the full version, please go here: https://fs8.formsite.com/medved44/form33/index.html ]]>
Mon, 19 Oct 2015 20:54:13 GMThttps://www.slideshare.net/MikePinelisPhD/smart-contact-lenses-technologies-market-research-report-sampleMikePinelisPhD@slideshare.net(MikePinelisPhD)Smart Contact Lenses Technologies -- market research report (sample)MikePinelisPhDWith nearly one billion units shipped worldwide in 2015 and annual growth rate of 6-7%, contact lenses are already a huge business. Smart contact lenses can potentially become an even larger market and present a unique business opportunity. Unlike other types of wearable devices such as activity trackers, smart contact lenses are only in the early stages of the commercialization cycle and, as such, provide a lucrative target for investors, system developers, sensor makers, and medical device companies.
This detailed 131-slide report provides a comprehensive overview of start contact lenses technologies and addresses several key questions such as:
● What are the applications and opportunities for smart contact lenses?
● Who are the main players in the smart contact lens space?
● What intellectual property (IP) is being developed for smart contact lenses?
● Which flexible technologies are being used or have the potential to be used?
● What are the existing and emerging applications?
● What are the key related technologies such as ocular implants, smart glasses, as well as virtual and augmented reality?
● Who are the key players and participants from R&D and commercialization perspective?
To order the full version, please go here: https://fs8.formsite.com/medved44/form33/index.html <img alt="" src="//cdn.slidesharecdn.com/ss_thumbnails/151019smartcontactlensesreport-sample-151019205413-lva1-app6891-thumbnail-2.jpg?cb=1445288336" style="border:1px solid #C3E6D8;float:right;" /><br> With nearly one billion units shipped worldwide in 2015 and annual growth rate of 6-7%, contact lenses are already a huge business. Smart contact lenses can potentially become an even larger market and present a unique business opportunity. Unlike other types of wearable devices such as activity trackers, smart contact lenses are only in the early stages of the commercialization cycle and, as such, provide a lucrative target for investors, system developers, sensor makers, and medical device companies.
This detailed 131-slide report provides a comprehensive overview of start contact lenses technologies and addresses several key questions such as:
● What are the applications and opportunities for smart contact lenses?
● Who are the main players in the smart contact lens space?
● What intellectual property (IP) is being developed for smart contact lenses?
● Which flexible technologies are being used or have the potential to be used?
● What are the existing and emerging applications?
● What are the key related technologies such as ocular implants, smart glasses, as well as virtual and augmented reality?
● Who are the key players and participants from R&amp;D and commercialization perspective?
To order the full version, please go here: https://fs8.formsite.com/medved44/form33/index.html

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67791//cdn.slidesharecdn.com/ss_thumbnails/151019smartcontactlensesreport-sample-151019205413-lva1-app6891-thumbnail-2.jpg?cb=1445288336presentationBlackhttp://activitystrea.ms/schema/1.0/posthttp://activitystrea.ms/schema/1.0/posted1Apple's Smart Sensor Technologies -- market research report (sample)https://www.slideshare.net/MikePinelisPhD/apples-smart-sensor-technologies-market-research-report-sample
150819applesmartsensorreport-samplepdfcreator-150819203320-lva1-app6892 This comprehensive 204-page report covers the latest and emerging sensors, microsystems, and MEMS technologies which Apple is developing and using for its products including the iPhone and the Watch. To order the full version, please go here: https://fs8.formsite.com/medved44/form33/index.html]]>
This comprehensive 204-page report covers the latest and emerging sensors, microsystems, and MEMS technologies which Apple is developing and using for its products including the iPhone and the Watch. To order the full version, please go here: https://fs8.formsite.com/medved44/form33/index.html]]>
Wed, 19 Aug 2015 20:33:20 GMThttps://www.slideshare.net/MikePinelisPhD/apples-smart-sensor-technologies-market-research-report-sampleMikePinelisPhD@slideshare.net(MikePinelisPhD)Apple's Smart Sensor Technologies -- market research report (sample)MikePinelisPhDThis comprehensive 204-page report covers the latest and emerging sensors, microsystems, and MEMS technologies which Apple is developing and using for its products including the iPhone and the Watch. To order the full version, please go here: https://fs8.formsite.com/medved44/form33/index.html<img alt="" src="//cdn.slidesharecdn.com/ss_thumbnails/150819applesmartsensorreport-samplepdfcreator-150819203320-lva1-app6892-thumbnail-2.jpg?cb=1440183524" style="border:1px solid #C3E6D8;float:right;" /><br> This comprehensive 204-page report covers the latest and emerging sensors, microsystems, and MEMS technologies which Apple is developing and using for its products including the iPhone and the Watch. To order the full version, please go here: https://fs8.formsite.com/medved44/form33/index.html

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16450//cdn.slidesharecdn.com/ss_thumbnails/150401medicalmems2015-conferenceguide-150402192037-conversion-gate01-thumbnail-2.jpg?cb=1428002561presentationBlackhttp://activitystrea.ms/schema/1.0/posthttp://activitystrea.ms/schema/1.0/posted125 Most Interesting Medical MEMS and Sensors Projectshttps://www.slideshare.net/MikePinelisPhD/140804-25-most-interesting-medical-mems-sensors
14080425mostinterestingmedicalmemssensors-140807164103-phpapp02 This presentation outlines some of the most exciting medical MEMS and sensors devices that were introduced to the marketplace in the past few years. Some of the devices are already in volume production, and some are still being commercialized. ]]>
This presentation outlines some of the most exciting medical MEMS and sensors devices that were introduced to the marketplace in the past few years. Some of the devices are already in volume production, and some are still being commercialized. ]]>
Thu, 07 Aug 2014 16:41:03 GMThttps://www.slideshare.net/MikePinelisPhD/140804-25-most-interesting-medical-mems-sensorsMikePinelisPhD@slideshare.net(MikePinelisPhD)25 Most Interesting Medical MEMS and Sensors ProjectsMikePinelisPhDThis presentation outlines some of the most exciting medical MEMS and sensors devices that were introduced to the marketplace in the past few years. Some of the devices are already in volume production, and some are still being commercialized. <img alt="" src="//cdn.slidesharecdn.com/ss_thumbnails/14080425mostinterestingmedicalmemssensors-140807164103-phpapp02-thumbnail-2.jpg?cb=1421753147" style="border:1px solid #C3E6D8;float:right;" /><br> This presentation outlines some of the most exciting medical MEMS and sensors devices that were introduced to the marketplace in the past few years. Some of the devices are already in volume production, and some are still being commercialized.

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382702//cdn.slidesharecdn.com/ss_thumbnails/14080425mostinterestingmedicalmemssensors-140807164103-phpapp02-thumbnail-2.jpg?cb=1421753147presentationWhitehttp://activitystrea.ms/schema/1.0/posthttp://activitystrea.ms/schema/1.0/posted1How to Pick a MEMS Foundry: Top 10 Selection Criteriahttps://www.slideshare.net/MikePinelisPhD/140327-micrel-mems-foundry-selection-whitepaper-final-version
140327micrelmemsfoundryselectionwhitepaper-finalversion-140411161257-phpapp02 This whitepaper outlines the top selection criteria for selections a MEMS foundry. It might seem arcane for those in the semiconductor industry, but the fact is that there is no common MEMS processing platform that is shared between foundries. The MEMS industry does not have an equivalent to the Simulation Program with Integrated Circuit Emphasis (SPICE) model for particular process models. Process development for MEMS products is very much product and design specific. The MEMS industry is coming to the realization that there will always be multiple process platforms and that these can serve as a means of differentiation between foundries. The high risk and lengthy (read: costly) development of MEMS processing is not the core business of large semiconductor foundries. These foundries are more ROI driven along a set of predictable parameters; wafer size, process steps/mask levels and production volumes. Smaller foundries specializing in MEMS processing are willing to conduct early-stage process development for proof-of-concept against non-recurring engineering charges (NRE) and accept small batch orders for development and production. For a MEMS product company, the foundry selection process should include foundries that have the capability to provide services for prototyping, process development, and high-volume manufacturing. It is also important to select a foundry that can offer intelligent design and process feedback, and that cooperates on the processing specification to ensure manufacturability and high yielding products.]]>
This whitepaper outlines the top selection criteria for selections a MEMS foundry. It might seem arcane for those in the semiconductor industry, but the fact is that there is no common MEMS processing platform that is shared between foundries. The MEMS industry does not have an equivalent to the Simulation Program with Integrated Circuit Emphasis (SPICE) model for particular process models. Process development for MEMS products is very much product and design specific. The MEMS industry is coming to the realization that there will always be multiple process platforms and that these can serve as a means of differentiation between foundries. The high risk and lengthy (read: costly) development of MEMS processing is not the core business of large semiconductor foundries. These foundries are more ROI driven along a set of predictable parameters; wafer size, process steps/mask levels and production volumes. Smaller foundries specializing in MEMS processing are willing to conduct early-stage process development for proof-of-concept against non-recurring engineering charges (NRE) and accept small batch orders for development and production. For a MEMS product company, the foundry selection process should include foundries that have the capability to provide services for prototyping, process development, and high-volume manufacturing. It is also important to select a foundry that can offer intelligent design and process feedback, and that cooperates on the processing specification to ensure manufacturability and high yielding products.]]>
Fri, 11 Apr 2014 16:12:57 GMThttps://www.slideshare.net/MikePinelisPhD/140327-micrel-mems-foundry-selection-whitepaper-final-versionMikePinelisPhD@slideshare.net(MikePinelisPhD)How to Pick a MEMS Foundry: Top 10 Selection CriteriaMikePinelisPhDThis whitepaper outlines the top selection criteria for selections a MEMS foundry. It might seem arcane for those in the semiconductor industry, but the fact is that there is no common MEMS processing platform that is shared between foundries. The MEMS industry does not have an equivalent to the Simulation Program with Integrated Circuit Emphasis (SPICE) model for particular process models. Process development for MEMS products is very much product and design specific. The MEMS industry is coming to the realization that there will always be multiple process platforms and that these can serve as a means of differentiation between foundries. The high risk and lengthy (read: costly) development of MEMS processing is not the core business of large semiconductor foundries. These foundries are more ROI driven along a set of predictable parameters; wafer size, process steps/mask levels and production volumes. Smaller foundries specializing in MEMS processing are willing to conduct early-stage process development for proof-of-concept against non-recurring engineering charges (NRE) and accept small batch orders for development and production. For a MEMS product company, the foundry selection process should include foundries that have the capability to provide services for prototyping, process development, and high-volume manufacturing. It is also important to select a foundry that can offer intelligent design and process feedback, and that cooperates on the processing specification to ensure manufacturability and high yielding products.<img alt="" src="//cdn.slidesharecdn.com/ss_thumbnails/140327micrelmemsfoundryselectionwhitepaper-finalversion-140411161257-phpapp02-thumbnail-2.jpg?cb=1397237144" style="border:1px solid #C3E6D8;float:right;" /><br> This whitepaper outlines the top selection criteria for selections a MEMS foundry. It might seem arcane for those in the semiconductor industry, but the fact is that there is no common MEMS processing platform that is shared between foundries. The MEMS industry does not have an equivalent to the Simulation Program with Integrated Circuit Emphasis (SPICE) model for particular process models. Process development for MEMS products is very much product and design specific. The MEMS industry is coming to the realization that there will always be multiple process platforms and that these can serve as a means of differentiation between foundries. The high risk and lengthy (read: costly) development of MEMS processing is not the core business of large semiconductor foundries. These foundries are more ROI driven along a set of predictable parameters; wafer size, process steps/mask levels and production volumes. Smaller foundries specializing in MEMS processing are willing to conduct early-stage process development for proof-of-concept against non-recurring engineering charges (NRE) and accept small batch orders for development and production. For a MEMS product company, the foundry selection process should include foundries that have the capability to provide services for prototyping, process development, and high-volume manufacturing. It is also important to select a foundry that can offer intelligent design and process feedback, and that cooperates on the processing specification to ensure manufacturability and high yielding products.

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47820//cdn.slidesharecdn.com/ss_thumbnails/140327micrelmemsfoundryselectionwhitepaper-finalversion-140411161257-phpapp02-thumbnail-2.jpg?cb=1397237144documentBlackhttp://activitystrea.ms/schema/1.0/posthttp://activitystrea.ms/schema/1.0/posted1SAES Packaging Services for MEMS Deviceshttps://www.slideshare.net/MikePinelisPhD/saes-packaging-service-introduction-2013-0
140305saespackagingserviceintroduction20130-140305164126-phpapp02 Device packaging is one of the most critical aspects for protecting and ensuring long term stability of MEMS based sensors and actuators. High‐performance classes of devices require robust packaging solutions that enable long term stability under a variety of operating conditions.
SAES® Group is now offering a fully integrated MEMS vacuum packaging service that includes the getter deposition on the lid (PageLid), the hermetic sealing process, as well as the RGA and leak rate tests to verify vacuum levels. The use of state-of-the-art sealing equipment, operating in a class 100 clean room, enables the exclusive capability to deliver high quality standard services at competitive costs.
Read more about our packaging service visiting our website at: http://www.saesgetters.com/products/packaging-service. ]]>
Device packaging is one of the most critical aspects for protecting and ensuring long term stability of MEMS based sensors and actuators. High‐performance classes of devices require robust packaging solutions that enable long term stability under a variety of operating conditions.
SAES® Group is now offering a fully integrated MEMS vacuum packaging service that includes the getter deposition on the lid (PageLid), the hermetic sealing process, as well as the RGA and leak rate tests to verify vacuum levels. The use of state-of-the-art sealing equipment, operating in a class 100 clean room, enables the exclusive capability to deliver high quality standard services at competitive costs.
Read more about our packaging service visiting our website at: http://www.saesgetters.com/products/packaging-service. ]]>
Wed, 05 Mar 2014 16:41:26 GMThttps://www.slideshare.net/MikePinelisPhD/saes-packaging-service-introduction-2013-0MikePinelisPhD@slideshare.net(MikePinelisPhD)SAES Packaging Services for MEMS DevicesMikePinelisPhDDevice packaging is one of the most critical aspects for protecting and ensuring long term stability of MEMS based sensors and actuators. High‐performance classes of devices require robust packaging solutions that enable long term stability under a variety of operating conditions.
SAES® Group is now offering a fully integrated MEMS vacuum packaging service that includes the getter deposition on the lid (PageLid), the hermetic sealing process, as well as the RGA and leak rate tests to verify vacuum levels. The use of state-of-the-art sealing equipment, operating in a class 100 clean room, enables the exclusive capability to deliver high quality standard services at competitive costs.
Read more about our packaging service visiting our website at: http://www.saesgetters.com/products/packaging-service. <img alt="" src="//cdn.slidesharecdn.com/ss_thumbnails/140305saespackagingserviceintroduction20130-140305164126-phpapp02-thumbnail-2.jpg?cb=1394037837" style="border:1px solid #C3E6D8;float:right;" /><br> Device packaging is one of the most critical aspects for protecting and ensuring long term stability of MEMS based sensors and actuators. High‐performance classes of devices require robust packaging solutions that enable long term stability under a variety of operating conditions.
SAES® Group is now offering a fully integrated MEMS vacuum packaging service that includes the getter deposition on the lid (PageLid), the hermetic sealing process, as well as the RGA and leak rate tests to verify vacuum levels. The use of state-of-the-art sealing equipment, operating in a class 100 clean room, enables the exclusive capability to deliver high quality standard services at competitive costs.
Read more about our packaging service visiting our website at: http://www.saesgetters.com/products/packaging-service.

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13130//cdn.slidesharecdn.com/ss_thumbnails/memsjournal-marketintelligenceservices-140210120809-phpapp02-thumbnail-2.jpg?cb=1392034802documentBlackhttp://activitystrea.ms/schema/1.0/posthttp://activitystrea.ms/schema/1.0/posted1STMicroelectronics MEMS Microphone -- Reverse Engineering Analysishttps://www.slideshare.net/MikePinelisPhD/stmicroelectronics-mems-microphone-reverse-engineering-analysis
131005reverseengineeringofstmmicrophone-memsjournal-140127155435-phpapp01 This is a reverse engineering report of the STMicroelectronics MP34DT01 omnidirectional digital microphone. Details include a full description, tear down analysis and 3D model of the MEMS microphone with cross-sections and SEM images. The reports also includes a full review of the packaging strategy and a description of the sensor assembly process. Furthermore the report has 40 descriptive images, background on the application, performance specifications, interconnect strategies, materials used, EMC strategy description, an electrical schematic, chip attachment means, strengths and weaknesses of the design and links to the patent, data sheets and more.
The report is extremely useful for engineers and business leaders looking to better understand MEMS microphone design, packaging and assemblies processes. It is also beneficial within the MEMS microphone community as a competitive analysis tool.]]>
This is a reverse engineering report of the STMicroelectronics MP34DT01 omnidirectional digital microphone. Details include a full description, tear down analysis and 3D model of the MEMS microphone with cross-sections and SEM images. The reports also includes a full review of the packaging strategy and a description of the sensor assembly process. Furthermore the report has 40 descriptive images, background on the application, performance specifications, interconnect strategies, materials used, EMC strategy description, an electrical schematic, chip attachment means, strengths and weaknesses of the design and links to the patent, data sheets and more.
The report is extremely useful for engineers and business leaders looking to better understand MEMS microphone design, packaging and assemblies processes. It is also beneficial within the MEMS microphone community as a competitive analysis tool.]]>
Mon, 27 Jan 2014 15:54:35 GMThttps://www.slideshare.net/MikePinelisPhD/stmicroelectronics-mems-microphone-reverse-engineering-analysisMikePinelisPhD@slideshare.net(MikePinelisPhD)STMicroelectronics MEMS Microphone -- Reverse Engineering AnalysisMikePinelisPhDThis is a reverse engineering report of the STMicroelectronics MP34DT01 omnidirectional digital microphone. Details include a full description, tear down analysis and 3D model of the MEMS microphone with cross-sections and SEM images. The reports also includes a full review of the packaging strategy and a description of the sensor assembly process. Furthermore the report has 40 descriptive images, background on the application, performance specifications, interconnect strategies, materials used, EMC strategy description, an electrical schematic, chip attachment means, strengths and weaknesses of the design and links to the patent, data sheets and more.
The report is extremely useful for engineers and business leaders looking to better understand MEMS microphone design, packaging and assemblies processes. It is also beneficial within the MEMS microphone community as a competitive analysis tool.<img alt="" src="//cdn.slidesharecdn.com/ss_thumbnails/131005reverseengineeringofstmmicrophone-memsjournal-140127155435-phpapp01-thumbnail-2.jpg?cb=1390855223" style="border:1px solid #C3E6D8;float:right;" /><br> This is a reverse engineering report of the STMicroelectronics MP34DT01 omnidirectional digital microphone. Details include a full description, tear down analysis and 3D model of the MEMS microphone with cross-sections and SEM images. The reports also includes a full review of the packaging strategy and a description of the sensor assembly process. Furthermore the report has 40 descriptive images, background on the application, performance specifications, interconnect strategies, materials used, EMC strategy description, an electrical schematic, chip attachment means, strengths and weaknesses of the design and links to the patent, data sheets and more.
The report is extremely useful for engineers and business leaders looking to better understand MEMS microphone design, packaging and assemblies processes. It is also beneficial within the MEMS microphone community as a competitive analysis tool.